//===--- SequenceAlgorithms.swift.gyb -------------------------*- swift -*-===//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2016 Apple Inc. and the Swift project authors
// Licensed under Apache License v2.0 with Runtime Library Exception
//
// See http://swift.org/LICENSE.txt for license information
// See http://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
//
//===----------------------------------------------------------------------===//

%{

# We know we will eventually get a Sequence.Element type.  Define
# a shorthand that we can use today.
GElement = "Iterator.Element"

orderingExplanation = """\
  /// The predicate must be a *strict weak ordering* over the elements. That
  /// is, for any elements `a`, `b`, and `c`, the following conditions must
  /// hold:
  ///
  /// - `areInIncreasingOrder(a, a)` is always `false`. (Irreflexivity)
  /// - If `areInIncreasingOrder(a, b)` and `areInIncreasingOrder(b, c)` are
  ///   both `true`, then `areInIncreasingOrder(a, c)` is also
  ///   `true`. (Transitive comparability)
  /// - Two elements are *incomparable* if neither is ordered before the other
  ///   according to the predicate. If `a` and `b` are incomparable, and `b`
  ///   and `c` are incomparable, then `a` and `c` are also incomparable.
  ///   (Transitive incomparability)
  ///"""

equivalenceExplanation = """\
  /// The predicate must be a *equivalence relation* over the elements. That
  /// is, for any elements `a`, `b`, and `c`, the following conditions must
  /// hold:
  ///
  /// - `areEquivalent(a, a)` is always `true`. (Reflexivity)
  /// - `areEquivalent(a, b)` implies `areEquivalent(b, a)`. (Symmetry)
  /// - If `areEquivalent(a, b)` and `areEquivalent(b, c)` are both `true`, then
  ///   `areEquivalent(a, c)` is also `true`. (Transitivity)
  ///"""

}%

//===----------------------------------------------------------------------===//
// enumerated()
//===----------------------------------------------------------------------===//

extension Sequence {
  /// Returns a sequence of pairs (*n*, *x*), where *n* represents a
  /// consecutive integer starting at zero, and *x* represents an element of
  /// the sequence.
  ///
  /// This example enumerates the characters of the string "Swift" and prints
  /// each character along with its place in the string.
  ///
  ///     for (n, c) in "Swift".characters.enumerated() {
  ///         print("\(n): '\(c)'")
  ///     }
  ///     // Prints "0: 'S'"
  ///     // Prints "1: 'w'"
  ///     // Prints "2: 'i'"
  ///     // Prints "3: 'f'"
  ///     // Prints "4: 't'"
  ///
  /// When enumerating a collection, the integer part of each pair is a counter
  /// for the enumeration, not necessarily the index of the paired value.
  /// These counters can only be used as indices in instances of zero-based,
  /// integer-indexed collections, such as `Array` and `ContiguousArray`. For
  /// other collections the counters may be out of range or of the wrong type
  /// to use as an index. To iterate over the elements of a collection with its
  /// indices, use the `zip(_:_:)` function.
  ///
  /// This example iterates over the indices and elements of a set, building a
  /// list of indices of names with five or fewer letters.
  ///
  ///     let names: Set = ["Sofia", "Camilla", "Martina", "Mateo", "Nicolás"]
  ///     var shorterIndices: [SetIndex<String>] = []
  ///     for (i, name) in zip(names.indices, names) {
  ///         if name.characters.count <= 5 {
  ///             shorterIndices.append(i)
  ///         }
  ///     }
  ///
  /// Now that the `shorterIndices` array holds the indices of the shorter
  /// names in the `names` set, you can use those indices to access elements in
  /// the set.
  ///
  ///     for i in shorterIndices {
  ///         print(names[i])
  ///     }
  ///     // Prints "Sofia"
  ///     // Prints "Mateo"
  ///
  /// - Returns: A sequence of pairs enumerating the sequence.
  public func enumerated() -> EnumeratedSequence<Self> {
    return EnumeratedSequence(_base: self)
  }
}

//===----------------------------------------------------------------------===//
// min(), max()
//===----------------------------------------------------------------------===//

% # Generate two versions: with explicit predicates and with
% # a Comparable requirement.
% for preds in [True, False]:
%   rethrows_ = "rethrows " if preds else ""

extension Sequence ${"" if preds else "where Iterator.Element : Comparable"} {

%   if preds:
  /// Returns the minimum element in the sequence, using the given predicate as
  /// the comparison between elements.
  ///
${orderingExplanation}
  /// This example shows how to use the `min(by:)` method on a
  /// dictionary to find the key-value pair with the lowest value.
  ///
  ///     let hues = ["Heliotrope": 296, "Coral": 16, "Aquamarine": 156]
  ///     let leastHue = hues.min { a, b in a.value < b.value }
  ///     print(leastHue)
  ///     // Prints "Optional(("Coral", 16))"
  ///
  /// - Parameter areInIncreasingOrder: A predicate that returns `true`
  ///   if its first argument should be ordered before its second
  ///   argument; otherwise, `false`.
  /// - Returns: The sequence's minimum element, according to
  ///   `areInIncreasingOrder`. If the sequence has no elements, returns
  ///   `nil`.
  ///
  /// - SeeAlso: `min()`
%   else:
  /// Returns the minimum element in the sequence.
  ///
  /// This example finds the smallest value in an array of height measurements.
  ///
  ///     let heights = [67.5, 65.7, 64.3, 61.1, 58.5, 60.3, 64.9]
  ///     let lowestHeight = heights.min()
  ///     print(lowestHeight)
  ///     // Prints "Optional(58.5)"
  ///
  /// - Returns: The sequence's minimum element. If the sequence has no
  ///   elements, returns `nil`.
  ///
  /// - SeeAlso: `min(by:)`
%   end
  @warn_unqualified_access
  public func min(
%   if preds:
    by areInIncreasingOrder: (${GElement}, ${GElement}) throws -> Bool
%   end
  ) ${rethrows_}-> ${GElement}? {
    var it = makeIterator()
    guard var result = it.next() else { return nil }
    for e in IteratorSequence(it) {
%   if preds:
      if try areInIncreasingOrder(e, result) { result = e }
%   else:
      if e < result { result = e }
%   end
    }
    return result
  }

%   if preds:
  /// Returns the maximum element in the sequence, using the given predicate
  /// as the comparison between elements.
  ///
${orderingExplanation}
  /// This example shows how to use the `max(by:)` method on a
  /// dictionary to find the key-value pair with the highest value.
  ///
  ///     let hues = ["Heliotrope": 296, "Coral": 16, "Aquamarine": 156]
  ///     let greatestHue = hues.max { a, b in a.value < b.value }
  ///     print(greatestHue)
  ///     // Prints "Optional(("Heliotrope", 296))"
  ///
  /// - Parameter areInIncreasingOrder:  A predicate that returns `true` if its
  ///   first argument should be ordered before its second argument;
  ///   otherwise, `false`.
  /// - Returns: The sequence's maximum element if the sequence is not empty;
  ///   otherwise, `nil`.
  ///
  /// - SeeAlso: `max()`
%   else:
  /// Returns the maximum element in the sequence.
  ///
  /// This example finds the smallest value in an array of height measurements.
  ///
  ///     let heights = [67.5, 65.7, 64.3, 61.1, 58.5, 60.3, 64.9]
  ///     let greatestHeight = heights.max()
  ///     print(greatestHeight)
  ///     // Prints "Optional(67.5)"
  ///
  /// - Returns: The sequence's maximum element. If the sequence has no
  ///   elements, returns `nil`.
  ///
  /// - SeeAlso: `max(by:)`
%   end
  @warn_unqualified_access
  public func max(
%   if preds:
    by areInIncreasingOrder: (${GElement}, ${GElement}) throws -> Bool
%   end
  ) ${rethrows_}-> ${GElement}? {
    var it = makeIterator()
    guard var result = it.next() else { return nil }
    for e in IteratorSequence(it) {
%   if preds:
      if try areInIncreasingOrder(result, e) { result = e }
%   else:
      if e > result { result = e }
%   end
    }
    return result
  }
}

% end

//===----------------------------------------------------------------------===//
// starts(with:)
//===----------------------------------------------------------------------===//

% # Generate two versions: with explicit predicates and with
% # an Equatable requirement.
% for preds in [True, False]:
%   rethrows_ = "rethrows " if preds else ""

extension Sequence ${"" if preds else "where Iterator.Element : Equatable"} {

%   if preds:
  /// Returns a Boolean value indicating whether the initial elements of the
  /// sequence are equivalent to the elements in another sequence, using
  /// the given predicate as the equivalence test.
  ///
${equivalenceExplanation}
  /// - Parameters:
  ///   - possiblePrefix: A sequence to compare to this sequence.
  ///   - areEquivalent: A predicate that returns `true` if its two arguments
  ///     are equivalent; otherwise, `false`.
  /// - Returns: `true` if the initial elements of the sequence are equivalent
  ///   to the elements of `possiblePrefix`; otherwise, `false`. If
  ///   `possiblePrefix` has no elements, the return value is `true`.
  ///
  /// - SeeAlso: `starts(with:)`
%   else:
  /// Returns a Boolean value indicating whether the initial elements of the
  /// sequence are the same as the elements in another sequence.
  ///
  /// This example tests whether one countable range begins with the elements
  /// of another countable range.
  ///
  ///     let a = 1...3
  ///     let b = 1...10
  ///
  ///     print(b.starts(with: a))
  ///     // Prints "true"
  ///
  /// Passing a sequence with no elements or an empty collection as
  /// `possiblePrefix` always results in `true`.
  ///
  ///     print(b.starts(with: []))
  ///     // Prints "true"
  ///
  /// - Parameter possiblePrefix: A sequence to compare to this sequence.
  /// - Returns: `true` if the initial elements of the sequence are the same as
  ///   the elements of `possiblePrefix`; otherwise, `false`. If
  ///   `possiblePrefix` has no elements, the return value is `true`.
  ///
  /// - SeeAlso: `starts(with:by:)`
%   end
  public func starts<PossiblePrefix>(
    with possiblePrefix: PossiblePrefix${"," if preds else ""}
%   if preds:
    by areEquivalent: (${GElement}, ${GElement}) throws -> Bool
%   end
  ) ${rethrows_}-> Bool
    where
    PossiblePrefix : Sequence,
    PossiblePrefix.${GElement} == ${GElement} {

    var possiblePrefixIterator = possiblePrefix.makeIterator()
    for e0 in self {
      if let e1 = possiblePrefixIterator.next() {
        if ${"try !areEquivalent(e0, e1)" if preds else "e0 != e1"} {
          return false
        }
      }
      else {
        return true
      }
    }
    return possiblePrefixIterator.next() == nil
  }
}

% end

//===----------------------------------------------------------------------===//
// elementsEqual()
//===----------------------------------------------------------------------===//

% # Generate two versions: with explicit predicates and with
% # an Equatable requirement.
% for preds in [True, False]:
%   rethrows_ = "rethrows " if preds else ""

extension Sequence ${"" if preds else "where Iterator.Element : Equatable"} {

%   if preds:
  /// Returns a Boolean value indicating whether this sequence and another
  /// sequence contain equivalent elements, using the given predicate as the
  /// equivalence test.
  ///
  /// At least one of the sequences must be finite.
  ///
${equivalenceExplanation}
  /// - Parameters:
  ///   - other: A sequence to compare to this sequence.
  ///   - areEquivalent: A predicate that returns `true` if its two arguments
  ///     are equivalent; otherwise, `false`.
  /// - Returns: `true` if this sequence and `other` contain equivalent items,
  ///   using `areEquivalent` as the equivalence test; otherwise, `false.`
  ///
  /// - SeeAlso: `elementsEqual(_:)`
%   else:
  /// Returns a Boolean value indicating whether this sequence and another
  /// sequence contain the same elements in the same order.
  ///
  /// At least one of the sequences must be finite.
  ///
  /// This example tests whether one countable range shares the same elements
  /// as another countable range and an array.
  ///
  ///     let a = 1...3
  ///     let b = 1...10
  ///
  ///     print(a.elementsEqual(b))
  ///     // Prints "false"
  ///     print(a.elementsEqual([1, 2, 3]))
  ///     // Prints "true"
  ///
  /// - Parameter other: A sequence to compare to this sequence.
  /// - Returns: `true` if this sequence and `other` contain the same elements
  ///   in the same order.
  ///
  /// - SeeAlso: `elementsEqual(_:by:)`
%   end
  public func elementsEqual<OtherSequence>(
    _ other: OtherSequence${"," if preds else ""}
%   if preds:
    by areEquivalent: (${GElement}, ${GElement}) throws -> Bool
%   end
  ) ${rethrows_}-> Bool
    where
    OtherSequence: Sequence,
    OtherSequence.${GElement} == ${GElement} {

    var iter1 = self.makeIterator()
    var iter2 = other.makeIterator()
    while true {
      switch (iter1.next(), iter2.next()) {
      case let (e1?, e2?):
        if ${'try !areEquivalent(e1, e2)' if preds else 'e1 != e2'} {
          return false
        }
      case (_?, nil),
           (nil, _?):
        return false
      case (nil, nil):
        return true
      }
    }
  }
}

% end

//===----------------------------------------------------------------------===//
// lexicographicallyPrecedes()
//===----------------------------------------------------------------------===//

% # Generate two versions: with explicit predicates and with
% # Comparable requirement.
% for preds in [True, False]:
%   rethrows_ = "rethrows " if preds else ""

extension Sequence ${"" if preds else "where Iterator.Element : Comparable"} {

%   if preds:
  /// Returns a Boolean value indicating whether the sequence precedes another
  /// sequence in a lexicographical (dictionary) ordering, using the given
  /// predicate to compare elements.
  ///
${orderingExplanation}
  /// - Parameters:
  ///   - other: A sequence to compare to this sequence.
  ///   - areInIncreasingOrder:  A predicate that returns `true` if its first
  ///     argument should be ordered before its second argument; otherwise,
  ///     `false`.
  /// - Returns: `true` if this sequence precedes `other` in a dictionary
  ///   ordering as ordered by `areInIncreasingOrder`; otherwise, `false`.
  ///
  /// - Note: This method implements the mathematical notion of lexicographical
  ///   ordering, which has no connection to Unicode.  If you are sorting
  ///   strings to present to the end user, use `String` APIs that perform
  ///   localized comparison instead.
  /// - SeeAlso: `lexicographicallyPrecedes(_:)`
%   else:
  /// Returns a Boolean value indicating whether the sequence precedes another
  /// sequence in a lexicographical (dictionary) ordering, using the
  /// less-than operator (`<`) to compare elements.
  ///
  /// This example uses the `lexicographicallyPrecedes` method to test which
  /// array of integers comes first in a lexicographical ordering.
  ///
  ///     let a = [1, 2, 2, 2]
  ///     let b = [1, 2, 3, 4]
  ///
  ///     print(a.lexicographicallyPrecedes(b))
  ///     // Prints "true"
  ///     print(b.lexicographicallyPrecedes(b))
  ///     // Prints "false"
  ///
  /// - Parameter other: A sequence to compare to this sequence.
  /// - Returns: `true` if this sequence precedes `other` in a dictionary
  ///   ordering; otherwise, `false`.
  ///
  /// - Note: This method implements the mathematical notion of lexicographical
  ///   ordering, which has no connection to Unicode.  If you are sorting
  ///   strings to present to the end user, use `String` APIs that
  ///   perform localized comparison.
  /// - SeeAlso: `lexicographicallyPrecedes(_:by:)`
%   end
  public func lexicographicallyPrecedes<OtherSequence>(
    _ other: OtherSequence${"," if preds else ""}
%   if preds:
    by areInIncreasingOrder:
      (${GElement}, ${GElement}) throws -> Bool
%   end
  ) ${rethrows_}-> Bool
    where
    OtherSequence : Sequence,
    OtherSequence.${GElement} == ${GElement} {

    var iter1 = self.makeIterator()
    var iter2 = other.makeIterator()
    while true {
      if let e1 = iter1.next() {
        if let e2 = iter2.next() {
          if ${"try areInIncreasingOrder(e1, e2)" if preds else "e1 < e2"} {
            return true
          }
          if ${"try areInIncreasingOrder(e2, e1)" if preds else "e2 < e1"} {
            return false
          }
          continue // Equivalent
        }
        return false
      }

      return iter2.next() != nil
    }
  }
}

% end

//===----------------------------------------------------------------------===//
// contains()
//===----------------------------------------------------------------------===//

extension Sequence where Iterator.Element : Equatable {
  /// Returns a Boolean value indicating whether the sequence contains the
  /// given element.
  ///
  /// This example checks to see whether a favorite actor is in an array
  /// storing a movie's cast.
  ///
  ///     let cast = ["Vivien", "Marlon", "Kim", "Karl"]
  ///     print(cast.contains("Marlon"))
  ///     // Prints "true"
  ///     print(cast.contains("James"))
  ///     // Prints "false"
  ///
  /// - Parameter element: The element to find in the sequence.
  /// - Returns: `true` if the element was found in the sequence; otherwise,
  ///   `false`.
  public func contains(_ element: ${GElement}) -> Bool {
    if let result = _customContainsEquatableElement(element) {
      return result
    }

    for e in self {
      if e == element {
        return true
      }
    }
    return false
  }
}

extension Sequence {
  /// Returns a Boolean value indicating whether the sequence contains an
  /// element that satisfies the given predicate.
  ///
  /// You can use the predicate to check for an element of a type that
  /// doesn't conform to the `Equatable` protocol, such as the
  /// `HTTPResponse` enumeration in this example.
  ///
  ///     enum HTTPResponse {
  ///         case ok
  ///         case error(Int)
  ///     }
  ///
  ///     let lastThreeResponses: [HTTPResponse] = [.ok, .ok, .error(404)]
  ///     let hadError = lastThreeResponses.contains { element in
  ///         if case .error = element {
  ///             return true
  ///         } else {
  ///             return false
  ///         }
  ///     }
  ///     // 'hadError' == true
  ///
  /// Alternatively, a predicate can be satisfied by a range of `Equatable`
  /// elements or a general condition. This example shows how you can check an
  /// array for an expense greater than $100.
  ///
  ///     let expenses = [21.37, 55.21, 9.32, 10.18, 388.77, 11.41]
  ///     let hasBigPurchase = expenses.contains { $0 > 100 }
  ///     // 'hasBigPurchase' == true
  ///
  /// - Parameter predicate: A closure that takes an element of the sequence
  ///   as its argument and returns a Boolean value that indicates whether
  ///   the passed element represents a match.
  /// - Returns: `true` if the sequence contains an element that satisfies
  ///   `predicate`; otherwise, `false`.
  public func contains(
    where predicate: (${GElement}) throws -> Bool
  ) rethrows -> Bool {
    for e in self {
      if try predicate(e) {
        return true
      }
    }
    return false
  }
}

//===----------------------------------------------------------------------===//
// reduce()
//===----------------------------------------------------------------------===//

extension Sequence {
  /// Returns the result of calling the given combining closure with each
  /// element of this sequence and an accumulating value.
  ///
  /// The `nextPartialResult` closure is called sequentially with an
  /// accumulating value initialized to `initialResult` and each
  /// element of the sequence. This example shows how to find the sum
  /// of an array of numbers.
  ///
  ///     let numbers = [1, 2, 3, 4]
  ///     let addTwo: (Int, Int) -> Int = { x, y in x + y }
  ///     let numberSum = numbers.reduce(0, addTwo)
  ///     // 'numberSum' == 10
  ///
  /// When `numbers.reduce(_:_:)` is called, the
  /// following steps occur:
  ///
  /// 1. The `nextPartialResult` closure is called with the initial
  ///    result and the first element of `numbers`, returning the sum:
  ///    `1`.
  /// 2. The closure is called again repeatedly with the previous call's
  ///    return value and each element of the sequence.
  /// 3. When the sequence is exhausted, the last value returned from the
  ///    closure is returned to the caller.
  ///
  /// - Parameters:
  ///   - initialResult: the initial accumulating value.
  ///   - nextPartialResult: A closure that combines an accumulating
  ///     value and an element of the sequence into a new accumulating
  ///     value, to be used in the next call of the
  ///     `nextPartialResult` closure or returned to the caller.
  /// - Returns: The final accumulated value.
  public func reduce<Result>(
    _ initialResult: Result,
    _ nextPartialResult:
      (_ partialResult: Result, ${GElement}) throws -> Result
  ) rethrows -> Result {
    var accumulator = initialResult
    for element in self {
      accumulator = try nextPartialResult(accumulator, element)
    }
    return accumulator
  }
}

//===----------------------------------------------------------------------===//
// reversed()
//===----------------------------------------------------------------------===//

extension Sequence {
  /// Returns an array containing the elements of this sequence in reverse
  /// order.
  ///
  /// The sequence must be finite.
  ///
  /// - Complexity: O(*n*), where *n* is the length of the sequence.
  ///
  /// - Returns: An array containing the elements of this sequence in
  ///   reverse order.
  public func reversed() -> [${GElement}] {
    // FIXME(performance): optimize to 1 pass?  But Array(self) can be
    // optimized to a memcpy() sometimes.  Those cases are usually collections,
    // though.
    var result = Array(self)
    let count = result.count
    for i in 0..<count/2 {
      swap(&result[i], &result[count - i - 1])
    }
    return result
  }
}

//===----------------------------------------------------------------------===//
// flatMap()
//===----------------------------------------------------------------------===//

extension Sequence {
  /// Returns an array containing the concatenated results of calling the
  /// given transformation with each element of this sequence.
  ///
  /// Use this method to receive a single-level collection when your
  /// transformation produces a sequence or collection for each element.
  ///
  /// In this example, note the difference in the result of using `map` and
  /// `flatMap` with a transformation that returns an array.
  ///
  ///     let numbers = [1, 2, 3, 4]
  ///
  ///     let mapped = numbers.map { Array(count: $0, repeatedValue: $0) }
  ///     // [[1], [2, 2], [3, 3, 3], [4, 4, 4, 4]]
  ///
  ///     let flatMapped = numbers.flatMap { Array(count: $0, repeatedValue: $0) }
  ///     // [1, 2, 2, 3, 3, 3, 4, 4, 4, 4]
  ///
  /// In fact, `s.flatMap(transform)`  is equivalent to
  /// `Array(s.map(transform).joined())`.
  ///
  /// - Parameter transform: A closure that accepts an element of this
  ///   sequence as its argument and returns a sequence or collection.
  /// - Returns: The resulting flattened array.
  ///
  /// - Complexity: O(*m* + *n*), where *m* is the length of this sequence
  ///   and *n* is the length of the result.
  /// - SeeAlso: `joined()`, `map(_:)`
  public func flatMap<SegmentOfResult : Sequence>(
    _ transform: (${GElement}) throws -> SegmentOfResult
  ) rethrows -> [SegmentOfResult.${GElement}] {
    var result: [SegmentOfResult.${GElement}] = []
    for element in self {
      result.append(contentsOf: try transform(element))
    }
    return result
  }
}

extension Sequence {
  /// Returns an array containing the non-`nil` results of calling the given
  /// transformation with each element of this sequence.
  ///
  /// Use this method to receive an array of nonoptional values when your
  /// transformation produces an optional value.
  ///
  /// In this example, note the difference in the result of using `map` and
  /// `flatMap` with a transformation that returns an optional `Int` value.
  ///
  ///     let possibleNumbers = ["1", "2", "three", "///4///", "5"]
  ///
  ///     let mapped: [Int?] = possibleNumbers.map { str in Int(str) }
  ///     // [1, 2, nil, nil, 5]
  ///
  ///     let flatMapped: [Int] = possibleNumbers.flatMap { str in Int(str) }
  ///     // [1, 2, 5]
  ///
  /// - Parameter transform: A closure that accepts an element of this
  ///   sequence as its argument and returns an optional value.
  /// - Returns: An array of the non-`nil` results of calling `transform`
  ///   with each element of the sequence.
  ///
  /// - Complexity: O(*m* + *n*), where *m* is the length of this sequence
  ///   and *n* is the length of the result.
  public func flatMap<ElementOfResult>(
    _ transform: (${GElement}) throws -> ElementOfResult?
  ) rethrows -> [ElementOfResult] {
    var result: [ElementOfResult] = []
    for element in self {
      if let newElement = try transform(element) {
        result.append(newElement)
      }
    }
    return result
  }
}

extension Sequence {
  @available(*, unavailable, renamed: "enumerated()")
  public func enumerate() -> EnumeratedSequence<Self> {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "min(by:)")
  public func minElement(
    _ isOrderedBefore: (Iterator.Element, Iterator.Element) throws -> Bool
  ) rethrows -> Iterator.Element? {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "max(by:)")
  public func maxElement(
    _ isOrderedBefore: (Iterator.Element, Iterator.Element) throws -> Bool
  ) rethrows -> Iterator.Element? {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "reversed()")
  public func reverse() -> [Iterator.Element] {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "starts(with:by:)")
  public func startsWith<PossiblePrefix>(
    _ possiblePrefix: PossiblePrefix,
    isEquivalent: (Iterator.Element, Iterator.Element) throws -> Bool
  ) rethrows-> Bool
    where
    PossiblePrefix : Sequence,
    PossiblePrefix.Iterator.Element == Iterator.Element {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "elementsEqual(_:by:)")
  public func elementsEqual<OtherSequence>(
    _ other: OtherSequence,
    isEquivalent: (${GElement}, ${GElement}) throws -> Bool
  ) rethrows -> Bool
    where
    OtherSequence: Sequence,
    OtherSequence.${GElement} == ${GElement} {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "lexicographicallyPrecedes(_:by:)")
  public func lexicographicalCompare<
    OtherSequence
  >(
    _ other: OtherSequence,
    isOrderedBefore: (${GElement}, ${GElement}) throws -> Bool
  ) rethrows -> Bool
    where
    OtherSequence : Sequence,
    OtherSequence.${GElement} == ${GElement} {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "contains(where:)")
  public func contains(
    _ predicate: (${GElement}) throws -> Bool
  ) rethrows -> Bool {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "reduce(_:_:)")
  public func reduce<Result>(
    _ initial: Result,
    combine: (_ partialResult: Result, ${GElement}) throws -> Result
  ) rethrows -> Result {
    Builtin.unreachable()
  }
}

extension Sequence where Iterator.Element : Comparable {
  @available(*, unavailable, renamed: "min()")
  public func minElement() -> Iterator.Element? {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "max()")
  public func maxElement() -> Iterator.Element? {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "starts(with:)")
  public func startsWith<PossiblePrefix>(
    _ possiblePrefix: PossiblePrefix
  ) -> Bool
    where
    PossiblePrefix : Sequence,
    PossiblePrefix.${GElement} == ${GElement} {
    Builtin.unreachable()
  }

  @available(*, unavailable, renamed: "lexicographicallyPrecedes")
  public func lexicographicalCompare<OtherSequence>(
    _ other: OtherSequence
  ) -> Bool
    where
    OtherSequence : Sequence,
    OtherSequence.${GElement} == ${GElement} {
    Builtin.unreachable()
  }
}
